Introduction

Mercury (Hg) is a globally distributed hazardous metal and is well known for its long-range transport, environmental persistence and toxicity (Kim et al., 2009; Selin, 2009; Schleicher et al., 2015). Hg is emitted to the atmosphere through natural and anthropogenic processes or reemission of previously deposited legacy Hg. It has three operationally defined forms: gaseous elemental Hg (GEM), reactive gaseous Hg (RGM) and particle-bound Hg (PBM) (Selin, 2009). In general, GEM (> 90 % of the total Hg in atmosphere) is fairly stable and can be transported globally, whereas RGM is rapidly deposited from the atmosphere in wet and dry deposition, and PBM is assumed to be transported more regionally (Selin, 2009; Fu et al., 2012). Recent measurements of PBM in several rural and urban areas have shown that Hg associated with particulate matter (PM) of size < 2.5 $\mathrm{\mu }$m (PM${}_{2.5}$-Hg) has typical concentrations < 100 pg m${}^{-\mathrm{3}}$ in background atmospheric environments (Liu et al., 2007; Fu et al., 2008; Kim et al., 2012), but exceeds 300 pg m${}^{-\mathrm{3}}$ in contaminated regions (Xiu et al., 2009; Zhu et al., 2014). PM${}_{2.5}$-Hg is of particular concern because, once inhaled, both Hg and its vectors might have adverse effects on human beings.

Mercury has seven stable isotopes (${}^{196}$Hg, ${}^{198}$Hg, ${}^{199}$Hg,${}^{\mathrm{\hspace{0.17em}200}}$Hg, ${}^{201}$Hg, ${}^{202}$Hg and ${}^{204}$Hg) and its isotopic ratios in the nature have attracted much interest in recent years (Yin et al., 2010; Hintelmann and Zheng, 2012; Blum et al., 2014; Cai and Chen, 2016). Previous studies have reported both mass-dependent fractionation (MDF, ${\mathit{\delta }}^{202}$Hg) and mass-independent fractionation (MIF, primarily observation of odd atomic weighed Hg isotopes, ${\mathrm{\Delta }}^{199}$Hg and ${\mathrm{\Delta }}^{201}$Hg) of Hg isotopes in environments (Hintelmann and Lu, 2003; Jackson et al., 2004, 2008; Bergquist and Blum, 2007; Gratz et al., 2010; Chen et al., 2012; Sherman et al., 2012). The nuclear volume effect (NVE) (Schauble, 2007) and magnetic isotope effect (MIE) (Buchachenko, 2009) are thought to be the main causes for odd-MIF (Bergquist and Blum, 2007; Gratz et al., 2010; Wiederhold et al., 2010; Sonke, 2011; Chen et al., 2012; Ghosh et al., 2013; Eiler et al., 2014). Theoretical and experimental data suggested a ${\mathrm{\Delta }}^{199}$Hg $/$ ${\mathrm{\Delta }}^{201}$Hg ratio about 1.6 for NVE (Zheng and Hintelmann, 2009, 2010b), and a ${\mathrm{\Delta }}^{199}$Hg $/$ ${\mathrm{\Delta }}^{201}$Hg ratio mostly between 1.0 and 1.3 for MIE as a result of photolytic reductions under aquatic (and atmospheric) conditions (Zheng and Hintelmann, 2009, 2010a; Malinovsky et al., 2010; Wiederhold et al., 2010; Sonke, 2011; Ghosh et al., 2013; Eiler et al., 2014). Over the past decade, studies have indicated that Hg isotope ratios are useful for differentiating Hg sources in terrestrial samples, such as sediments (Jackson et al., 2004; Feng et al., 2010; Ma et al., 2013), soils (Biswas et al., 2008; Zhang et al., 2013a) and biota (Sherman et al., 2013; Yin et al., 2013; Jackson, 2015), and for distinguishing potential biogeochemical processes that Hg had undergone (Jackson et al., 2013; Sherman et al., 2013; Yin et al., 2013; Masbou et al., 2015). Up to now, several studies have reported Hg isotopic compositions in atmospheric samples (Zambardi et al., 2009; Gratz et al., 2010; Chen et al., 2012; Sherman et al., 2012, 2015; Demers et al., 2013, 2015a; Rolison et al., 2013; Fu et al., 2014, 2016; Yuan et al., 2015; Das et al., 2016; Enrico et al., 2016). These studies reported large variations in ${\mathrm{\Delta }}^{199}$Hg and ${\mathit{\delta }}^{202}$Hg values for GEM (ranging from $-$0.41 to 0.06 ‰ for ${\mathrm{\Delta }}^{199}$Hg, and from $-$3.88 to 1.43 ‰ for ${\mathit{\delta }}^{202}$Hg) (Zambardi et al., 2009; Gratz et al., 2010; Sherman et al., 2010; Rolison et al., 2013; Yin et al., 2013; Demers et al., 2015b; Das et al., 2016; Enrico et al., 2016; Fu et al., 2016) and for Hg in precipitation (from 0.04 to 1.16 ‰ for ${\mathrm{\Delta }}^{199}$Hg, and from $-$4.37 to 1.48 ‰ for ${\mathit{\delta }}^{202}$Hg) (Gratz et al., 2010; Chen et al., 2012; Sherman et al., 2012, 2015; Demers et al., 2013; Wang et al., 2015b; Yuan et al., 2015). In addition, recent studies have found MIF of even Hg isotopes (even-MIF, ${\mathrm{\Delta }}^{200}$Hg) in natural samples mainly related to the atmosphere, rendering Hg a unique heavy metal having “three-dimensional” isotope systems (Chen et al., 2012).

While Hg isotopes in both GEM and RGM have drawn much attention, those of PBM are comparably less studied in the literature. Indeed, only several prior studies have focused on Hg isotopes in PBM. Rolison et al. (2013) reported, for the first time, ${\mathit{\delta }}^{202}$Hg (of $-$1.61 to $-$0.12 ‰) and ${\mathrm{\Delta }}^{199}$Hg values (of 0.36 to 1.36 ‰) for PBM from the Grand Bay area in the USA, and the ratios of ${\mathrm{\Delta }}^{199}$Hg $/$ ${\mathrm{\Delta }}^{201}$Hg close to 1 that was thought to be derived from in-aerosol photoreduction. Huang et al. (2015) measured Hg isotope ratios for two PM${}_{2.5}$ samples taken from Guiyang, China, with ${\mathit{\delta }}^{202}$Hg of $-$1.71 and $-$1.13 ‰ and ${\mathrm{\Delta }}^{199}$Hg of 0.21 and 0.16 ‰. Das et al. (2016) measured Hg isotopic compositions of PBM in PM${}_{10}$ from Kolkata, eastern India, and found negative MDF and varied values of ${\mathrm{\Delta }}^{199}$Hg between $-$0.31 and 0.33 ‰. These studies showed that the Hg isotope approach could be developed for tracking the sources and pathways of Hg species in the atmosphere.

China is one of the largest Hg emission countries in the world (Fu et al., 2012; Zhang et al., 2015), with a total estimated anthropogenic Hg emission of approximately 356 t in 2000 and 538 t in 2010 (Zhang et al., 2015). Coal combustion, nonferrous metal smelting, and cement production are the dominant Hg emission sources in China (collectively accounting for approximately over 80 % of the total Hg emission) (Zhang et al., 2015). Haze particles, especially PM${}_{2.5}$, which are among the most serious atmospheric pollutants in urban areas of China (Huang et al., 2014), are important carriers of Hg (Lin et al., 2015b; Schleicher et al., 2015). If PM${}_{2.5}$ is emitted from the same source as Hg (Huang et al., 2014; Lin et al., 2015b; Schleicher et al., 2015; Zhang et al., 2015), quantifying Hg isotopes may provide direct evidence for the sources of both Hg and PM${}_{2.5}$, as well as insight into the geochemical processes that they may have undergone.

In this study, we attempted to identify the sources of PM${}_{2.5}$-Hg in Beijing, the capital of China, using Hg isotopic composition coupled with meteorological and other geochemical parameters. We selected Beijing as the study site because, like many other Chinese megacities, Beijing has suffered severe PM${}_{2.5}$ pollution (Huang et al., 2014; Gao et al., 2015) and is considered as the most PBM polluted area in China (Schleicher et al., 2015). In the past decade, only a few prior studies quantified the Hg concentrations in PM${}_{2.5}$ samples collected from Beijing (Wang et al., 2006; Zhang et al., 2013b; Schleicher et al., 2015), while no research attempted to track its sources using the Hg isotope approach. The specific objectives of this study were (1) to characterize the seasonal variation in Hg isotope compositions in PM${}_{2.5}$ of Beijing and (2) to test the effectiveness of the Hg isotope technique for tracking the sources of the PM${}_{2.5}$-Hg.

Materials and methods

Field site and sampling method

Beijing (39.92${}^{\circ }$ N and 116.46${}^{\circ }$ E) has a population of over 21 million. It is located in a temperate warm zone with typical continental monsoon climate. The northwestern part of the greater Beijing metropolitan area is mountainous, while the southeastern part is flat. It has an average annual temperature of about 11.6 ${}^{\circ }$C, with a mean value of 24 ${}^{\circ }$C in summer and $-$2 ${}^{\circ }$C in winter. In the summer, the wind blows mainly from the southeast under the influence of the hot and humid East Asian monsoon, whereas the cold and dry monsoon blows from Siberia and Mongolia in the winter. The winter heating season in Beijing normally starts on 15 November and ends on 15 March.

PM${}_{2.5}$ was sampled from September 2013 to July 2014 using a high-volume PM${}_{2.5}$ sampler placed on the roof of a building (approximately 8 m above the ground) of the Institute of Atmospheric Physics, Chinese Academy of Sciences, which is located between the north 3rd and 4th ring of Beijing. The meteorological model showed that the arriving air masses were transported mainly by two directions, with the northwest winds dominant in winter and the southern winds mainly in summer. The sampling information is detailed in the Supplement (see Table S1). The PM${}_{2.5}$ samples were collected using a Tisch Environmental PM${}_{2.5}$ high-volume air sampler, which collects particles at a flow rate of 1.0 m${}^{\mathrm{3}}$ min${}^{-\mathrm{1}}$ through a PM${}_{2.5}$ size-selective inlet. As the particles travel through the size selective inlet the larger particles are trapped inside of the inlet, while the smaller-size (PM${}_{2.5})$ particles continue to travel through the PM${}_{2.5}$ inlet and are collected on a pre-combusted (450 ${}^{\circ }$C for 6 h) quartz fiber filter (Pallflex 2500 QAT-UP, 20 cm $\times$ 25 cm, Pallflex Product Co., USA). The mass of PM${}_{2.5}$ on each filter was measured using a gravimetric method by the mass difference before and after sampling. The filters were conditioned in a chamber with a relative humidity of about 48 % and a temperature of 20 $\pm$ 2 ${}^{\circ }$C for about 24 h before and after sampling. A field blank was also collected during sampling and the value (< 0.2 ng of Hg, $n$ $=$ 6) was negligible (< 2 %) compared to the total Hg mass contained in the PM${}_{2.5}$ samples. After sampling, each filter was recovered, wrapped with a pre-combusted (to eliminate Hg) aluminum film, and packed in a sealed plastic bag. The filters were brought back to the laboratory and stored at $-$20 ${}^{\circ }$C prior to analysis.

In order to better assign sources of Hg, we collected and measured 30 solid samples of different materials that may be potential Hg (and PM${}_{2.5})$ sources and that may contribute to PM${}_{2.5}$-Hg in Beijing. They included (i) 8 samples (including feed coal powder, bottom ash, desulfurization gypsum and fly ash) from two coal-fired power plants (from Hubei and Mongolia provinces); (ii) 6 samples from a Pb–Zn smelting plant (including blast furnace dust, dust of blast furnace slag, sintering dust, coke, return powder and agglomerate); (iii) 10 samples from a cement plant (including coal powder, raw meal, sandstone, clay, limestone, steel slag, sulfuric acid residue, desulfurization gypsum and cement clinker), 6 of which have been published previously (Wang et al., 2015b); (iv) 4 topsoil samples (surface horizon: organics mixed with mineral matter, these samples are not natural soil on typical soil profiles) from the Beijing center city (Olympic Park, Beihai Park, the Winter Palace and Renmin University of China (RUC)) and 2 dust samples from RUC (one building roof dust and one road dust); (v) 1 total suspended particle (TSP; the sampling of TSP was carried out using an in-house-constructed low-volume (about 1.8 m${}^{\mathrm{3}}$ h${}^{-\mathrm{1}})$ air sampler equipped with a TSP inlet, and a pre-cleaned mixed fiber filter (47 mm) was used for the TSP low-volume inlets) sample from the atmosphere of a rural area of Yanqing district, northwest of Beijing; and (vi) 2 urban road dust, 2 suburban road dust and 1 suburban topsoil samples from the city of Shijiazhuang, southwest of Beijing. Though automobile exhaust might also be a contributing source of PM${}_{2.5}$-Hg, we were not able to measure its Hg isotope ratios due to its exceedingly low Hg concentration (Won et al., 2007).

Materials and reagents

Materials and reagents used in this study were similar to those described in a previous study (Huang et al., 2015). A 0.2 M BrCl solution was prepared by mixing the distilled concentrated HCl with pre-heated (250 ${}^{\circ }$C, 12 h) KBr and KBrO${}_{\mathrm{3}}$ powders. Two SnCl${}_{\mathrm{2}}$ solutions of 20 and 3 % (wt) were prepared by dissolving in 1 M HCl and were used for online reduction of Hg for concentration and isotope measurements, respectively. A 20 % (wt) NH${}_{\mathrm{2}}$OH $\mathrm{⚫}$ HCl solution was used for BrCl neutralization.

Two international Hg standards NIST SRM 3133 and UM-Almaden were used as the reference materials for Hg isotope analysis. NIST SRM 997 thallium (20 ng mL${}^{-\mathrm{1}}$ Tl in 3 % HNO${}_{\mathrm{3}})$ was employed for mass bias correction (Chen et al., 2010; Huang et al., 2015). Two other reference materials, the solution Fluka 28 941 Hg (TraceCERT^®, Sigma-Aldrich) and the soil GBW07405 (National Center for Standard Materials, Beijing, China), were used as in-house isotope standards, and these were regularly measured for quality control of Hg concentration and isotope measurements. It is worth noting that Fluka 28 941 Hg is a standard different from ETH Fluka Hg (Jiskra et al., 2012; Smith et al., 2015).

Isotopic composition analysis

Mercury bound to PM${}_{2.5}$ and solid source materials was released via a dual-stage combustion protocol and was captured in a 5 mL 40 % acid mixture ($\mathrm{2}:\mathrm{4}:\mathrm{9}$ volumetric ratio of 10 M HCl, 15 M HNO${}_{\mathrm{3}}$ and Milli-Q water) (Huang et al., 2015). The detailed procedure is available in Huang et al. (2015). In brief, the filter samples were rolled into a cylinder and placed in a furnace quartz tube (25 mm OD, 22 mm ID, 1.0 m length), which was located in two series of combustion tube furnaces (BTF-1200C-S, Anhui BEQ Equipment Technology Ltd., China). The solid source samples were powdered, weighed and put into a sample quartz tube (20 mm OD, 18 mm ID, 10 cm length), which was capped with quartz wool (pre-cleaned at 500 ${}^{\circ }$C) at both ends to prevent particle emission. The sample tube was then placed into the large quartz tube of the furnace. The samples were combusted through a temperature-programmed routine in the dual-stage combustion and acid solution trapping system. An aliquot (50 $\mathrm{\mu }$L) of 0.2 M BrCl was added to the above trapping solution to stabilize the Hg${}^{\mathrm{2}+}$. The trapping solution for each sample was diluted to a final acid concentration of about 20 % and was stored at 4 ${}^{\circ }$C for the subsequent Hg concentration and isotope measurement. The accuracy and precision of the dual-stage combustion protocol were evaluated by the analysis of the certified reference material GBW07405 using the same digestion method. The detectable Hg in the procedural blank (< 0.2 ng, $n$ $=$ 12) of this dual-stage combustion method was negligible compared to the amount of total Hg (> 5 ng) in both PM${}_{2.5}$ samples and procedural standards.

Mercury isotope analyses were performed on the MC-ICP-MS (Nu Instruments Ltd., UK) at the State Key Laboratory of Environmental Geochemistry, Institute of Geochemistry, China. The details of the analytical procedures and the instrumental settings were given in previous studies (Huang et al., 2015; Lin et al., 2015a; Wang et al., 2015b; Yuan et al., 2015). In brief, a home-made cold-vapor generation system was coupled with an Aridus II desolvating nebulizer for respective Hg and Tl introductions. The Faraday cups were positioned to simultaneously collect five Hg isotopes and two Tl isotopes, including ${}^{205}$Tl (H3), ${}^{203}$Tl (H1), ${}^{202}$Hg (Ax), ${}^{201}$Hg (L1), ${}^{200}$Hg (L2), ${}^{199}$Hg (L3), and ${}^{198}$Hg (L4). The instrumental mass bias was double-corrected by both internal standard NIST SRM 997 Tl and by sample-standard bracketing (SSB) using the international standard NIST SRM 3133 Hg. The MDF of isotopes is represented by delta ($\mathit{\delta }$) notation in units of permil (‰) and defined as the following equation (Blum and Bergquist, 2007): $$\begin{array}{cc}{\mathit{\delta }}^x\mathrm{Hg}\left(\mathrm{‰}\right)& =[{\left({}^x,\mathrm{Hg},{/}^{198},\mathrm{Hg}\right)}_{\text{sample}}/{\left({}^x,\mathrm{Hg},{/}^{198},\mathrm{Hg}\right)}_{\text{NIST3133}}\\ & & -\mathrm{1}]\times 1000\end{array}$$ where $x$ $=$ 199, 200, 201, and 202. MIF is reported as the deviation of a measured delta value from the theoretically predicted value due to kinetic MDF according to the following equation: $${\mathrm{\Delta }}^x\mathrm{Hg}\left(\mathrm{‰}\right)={\mathit{\delta }}^x\mathrm{Hg}-\mathit{\beta }\times {\mathit{\delta }}^{202}\mathrm{Hg},$$ where the mass-dependent scaling factor $\mathit{\beta }$ is of about 0.252, 0.5024 and 0.752 for ${}^{199}$Hg, ${}^{200}$Hg and ${}^{201}$Hg, respectively (Blum and Bergquist, 2007).

The Fluka 28 941 Hg standard was carefully calibrated against the NIST SRM 3133 Hg and the long-term measurements yielded an average value of $-$1.00 $\pm$ 0.13 ‰ (2 SD, $n$ $=$ 15) for ${\mathit{\delta }}^{202}$Hg, with a precision similar to that (0.10 ‰, $n$ $=$ 114) obtained for NIST SRM 3133 Hg. Our repeated measurements of UM-Almaden and GBW07405 had average ${\mathit{\delta }}^{202}$Hg, ${\mathrm{\Delta }}^{199}$Hg and ${\mathrm{\Delta }}^{201}$Hg values of $-$0.60 $\pm$ 0.09, $-$0.01 $\pm$ 0.06 and $-$0.03 $\pm$ 0.06 ‰ (2 SD, $n$ $=$ 18) and of $-$1.77 $\pm$ 0.14, $-$0.29 $\pm$ 0.04 and $-$0.32 $\pm$ 0.06 ‰ (2 SD, $n$ $=$ 6), respectively, consistent with the data published in previous studies (Blum and Bergquist, 2007; Zheng et al., 2007; Smith et al., 2008; Carignan et al., 2009; Zambardi et al., 2009; Chen et al., 2010; Sherman et al., 2010; Wiederhold et al., 2010; Huang et al., 2015). In this study, the 2 SD uncertainties (0.14, 0.04 and 0.06 ‰ for ${\mathit{\delta }}^{202}$Hg, ${\mathrm{\Delta }}^{199}$Hg and ${\mathrm{\Delta }}^{201}$Hg) obtained for the soil reference GBW07405 were considered as the typical external uncertainties for some PM${}_{2.5}$ samples that were measured only once due to their limited mass. Otherwise, the uncertainties were calculated based on the multiple measurements (Tables S1 and S2).

Concentration measurements

A small fraction of each trapping solution (20 % acid mixture) was used to measure the Hg concentration by cold-vapor atomic fluorescence spectroscopy (Tekran 2500, Tekran^® Instruments Corporation, CA), with a precision better than 10 %. The recoveries of Hg for the standard GBW07405 and 30 solid samples were in the acceptable range of 95 to 105 %, but no recovery of Hg for the PM${}_{2.5}$ samples was determined due to limited availability of the samples. A 0.5 cm${}^{\mathrm{2}}$ punch from each filter sample was analyzed for organic and elemental carbon (OC $/$ EC) with a Desert Research Institute (DRI) model 2001 thermal–optical carbon analyzer (Atmoslytic Inc., Calabasas, CA, USA) following the Interagency Monitoring of Protected Visual Environments (IMPROVE) thermal evolution protocol (Wang et al., 2005). The calculated uncertainties were $\pm$10 % for the measured OC and EC data. The concentrations of other elements (e.g., Al, Cd, Co, Pb, Sb, Zn, K, Ca and Mg) were also measured for 14 of the PM${}_{2.5}$ samples and 16 of the selected potential source materials using ICP-MS or ICP-AES after total acid (HNO${}_{\mathrm{3}}$-HF-HClO${}_{\mathrm{4}})$ digestion. A 1.5 cm${}^{\mathrm{2}}$ punch from each filter sample and about 0.05 g of solid material samples were dissolved completely with HNO${}_{\mathrm{3}}$-HF-HClO${}_{\mathrm{4}}$. Note that, due to limited mass of PM${}_{2.5}$ samples, nine PM${}_{2.5}$ samples were exhausted after isotope analysis, and only 14 PM${}_{2.5}$ samples were analyzed for the other elements. The soil standard GBW07405 was digested using the same protocol and the measured concentrations of trace elements (TEs, including Hg) were consistent with the certified values.

Results

General characteristics of PM${}_{2.5}$

The contents of PM${}_{2.5}$, OC and EC for the 23 samples are presented in Table S1. The volumetric contents of PM${}_{2.5}$ ranged from 56 to 310 $\mathrm{\mu }$g m${}^{-\mathrm{3}}$ (average 120 $\pm$ 61 $\mathrm{\mu }$g m${}^{-\mathrm{3}}$), and were higher in autumn than the three other seasons (Fig. 1). The PM${}_{2.5}$ samples showed large variations in carbon concentrations, with OC ranged from 2.8 to 42 $\mathrm{\mu }$g m${}^{-\mathrm{3}}$ and EC from 1.2 to 9.2 $\mathrm{\mu }$g m${}^{-\mathrm{3}}$, averaging 12 $\pm$ 9.6 and 3.7 $\pm$ 2.3 $\mathrm{\mu }$g m${}^{-\mathrm{3}}$, respectively. The OC and EC contents in autumn (respective mean of 14 $\pm$ 11 and 4.9 $\pm$ 2.8 $\mathrm{\mu }$g m${}^{-\mathrm{3}}$, $n$ $=$ 6) and winter (mean of 19 $\pm$ 13 and 5.1 $\pm$ 2.3 $\mathrm{\mu }$g m${}^{-\mathrm{3}}$, $n$ $=$ 6) were approximately doubled compared to those in spring (mean of 7.7 $\pm$ 1.4 and 2.5 $\pm$ 0.7 $\mathrm{\mu }$g m${}^{-\mathrm{3}}$, $n$ $=$ 6) and summer (mean of 5.9 $\pm$ 1.8 and 2.0 $\pm$ 0.5 $\mathrm{\mu }$g m${}^{-\mathrm{3}}$, $n$ $=$ 5). Similar seasonal variation was also reported in a previous study (Zhou et al., 2012). When converted to the mass concentrations, the OC and EC contents were significantly ($p$ < 0.01) higher in winter (mean of 170 $\pm$ 49 and 50 $\pm$ 8 $\mathrm{\mu }$g g${}^{-\mathrm{1}}$, $n$ $=$ 6) than in other seasons (mean of 71 $\pm$ 18 and 25 $\pm$ 7.3 $\mathrm{\mu }$g g${}^{-\mathrm{1}}$, $n$ $=$ 17) (Table S1). Since EC contents were closely correlated with OC ($r^{\mathrm{2}}=$ 0.89, $p$ < 0.001), we discuss only EC contents in the following as an indicator for the source of PM, because EC is a significant pollutant of combustion source that is not readily modified by secondary processes in the atmosphere.

Seasonal variations in PM${}_{2.5}$ (a) and elemental carbon (b) contents, Hg concentrations (c) and Hg isotopic ratios (d–f) of the PM${}_{2.5}$ samples. For each box plot, the median is the 50th percentile and error bars extend from the 75th percentile to the maximum value (upper) and from the 25th percentile to the minimum value (lower). The small square in each box represents the seasonal mean value.

[Figure omitted. See PDF]

Seasonal variation in mercury concentration and isotopic composition

PM${}_{2.5}$-Hg volumetric concentrations and isotopic compositions are shown in Table S1. In general, the PM${}_{2.5}$-Hg concentrations ranged from 11 to 310 pg m${}^{-\mathrm{3}}$, with an average value of 90 $\pm$ 80 pg m${}^{-\mathrm{3}}$. These values were comparable to those reported at a rural site of Beijing (98 $\pm$ 113 pg m${}^{-\mathrm{3}})$ (Zhang et al., 2013b), indoor PM${}_{2.5}$ of Guangzhou (104 pg m${}^{-\mathrm{3}})$ (Huang et al., 2012) and several southeastern coastal cities (141 $\pm$ 128 pg m${}^{-\mathrm{3}})$ of China (Xu et al., 2013), but they were lower than those reported values for Guiyang (368 $\pm$ 676 pg m${}^{-\mathrm{3}})$ of China (Fu et al., 2011). From a global perspective, our PM${}_{2.5}$-Hg contents were much higher than those reported for urban areas of other countries such as Seoul in South Korea (23.9 $\pm$ 19.6 pg m${}^{-\mathrm{3}})$ (Kim et al., 2009), Gothenburg in Sweden (12.5 $\pm$ 5.9 pg m${}^{-\mathrm{3}})$ (Li et al., 2008) and Detroit in the USA (20.8 $\pm$ 30.0 pg m${}^{-\mathrm{3}})$ (Liu et al., 2007). The averaged PM${}_{2.5}$-Hg values showed an evident seasonal variation, with relatively higher value in winter (140 $\pm$ 99 pg m${}^{-\mathrm{3}})$ and lower in summer (22 $\pm$ 8.2 pg m${}^{-\mathrm{3}})$ (see Figs. 1 and 2). Previous studies also reported similar variation for Hg loads in atmospheric particles in Beijing (Wang et al., 2006; Schleicher et al., 2015); for example, the highest value of 2130 $\pm$ 420 pg m${}^{-\mathrm{3}}$ was found in winter 2004, while lower values were generally reported in summer (Wang et al., 2006; Schleicher et al., 2015).

Shown are relationships between ${\mathrm{\Delta }}^{199}$Hg and ${\mathit{\delta }}^{202}$Hg (a) and ${\mathrm{\Delta }}^{201}$Hg (b) for 23 PM${}_{2.5}$ samples. The gray areas are the ranges of Hg isotope compositions of potential source materials.

[Figure omitted. See PDF]

Seasonal variations were also observed for Hg isotopic compositions (see Figs. 1 and 2 and Table S1). The ${\mathit{\delta }}^{202}$Hg values ranged from $-$2.18 to 0.51 ‰ (average $-$0.71 $\pm$ 0.58 ‰, 1 SD, $n$ $=$ 23), with the lowest value of $-$2.18 ‰ found on 29 June 2014 (in summer), whereas the highest of 0.51 ‰ was found on 30 September 2013 (in autumn). Interestingly, all samples displayed a large ${\mathrm{\Delta }}^{199}$Hg variation from $-$0.53 to 0.57 ‰ (mean of 0.05 $\pm$ 0.29 ‰). Unlike ${\mathit{\delta }}^{202}$Hg, the lowest ${\mathrm{\Delta }}^{199}$Hg value ($-$0.53 ‰) was found in autumn (on 30 September 2013), whereas the highest value (0.57 ‰) was observed in spring (23 April 2014). Positive even-MIF of Hg isotope was also determined in all PM${}_{2.5}$-Hg, with ${\mathrm{\Delta }}^{200}$Hg ranging from 0.02 to 0.17 ‰, averaging 0.09 $\pm$ 0.04 ‰ (Table S1). Three previous studies reported negative ${\mathit{\delta }}^{202}$Hg (from $-$3.48 to $-$0.12 ‰) but significantly positive ${\mathrm{\Delta }}^{199}$Hg (from $-$0.31 to 1.36 ‰) for atmospheric particles (Rolison et al., 2013; Huang et al., 2015; Das et al., 2016).

Mercury content and isotope ratios in potential source materials

As showed in Table S2, the Hg concentrations of the potential source materials ranged widely from 0.35 to 7747 ng g${}^{-\mathrm{1}}$, with an exceptionally high value of 10 800 ng g${}^{-\mathrm{1}}$ for the sintering dust collected by the electrostatic precipitator in a smelting plant. Though the topsoil and road dust samples generally displayed relatively lower Hg concentrations (e.g., 23 to 408 ng g${}^{-\mathrm{1}}$, Table S2), the topsoil collected from Beihai Park in the 2nd ring of Beijing had an exceptionally high Hg content of 7747 ng g${}^{-\mathrm{1}}$. It is worth noting that these data were comparable to the mass-based Hg concentrations (150 to 2200 ng g${}^{-\mathrm{1}}$ with a mean value of 720 ng g${}^{-\mathrm{1}})$ for the 23 PM${}_{2.5}$ samples (Table S1).

The potential source materials also had a large variation in Hg isotope compositions (Figs. 2 and 3 and Table S2), with ${\mathit{\delta }}^{202}$Hg ranging from $-$2.67 to 0.62 ‰ (average $-$0.98 $\pm$ 0.79 ‰, 1 SD, $n$ $=$ 30), while ${\mathrm{\Delta }}^{199}$Hg ranged from $-$0.27 to 0.18 ‰ (mean $-$0.03 $\pm$ 0.11 ‰) and ${\mathrm{\Delta }}^{200}$Hg values ranged from $-$0.04 to 0.11 ‰ (mean 0.02 $\pm$ 0.04 ‰).

Comparison of isotopic compositions between the selected potential source materials and the PM${}_{2.5}$ samples. The ${\mathit{\delta }}^{202}$Hg values of PM${}_{2.5}$-Hg are within the ranges of the source materials, but the ${\mathrm{\Delta }}^{199}$Hg values are out of the range, suggesting contribution from other unknown sources or MIF during atmospheric processes.

[Figure omitted. See PDF]

Discussion

Previous studies have demonstrated that coal combustion, cement plant and non-ferrous metal smelting were main sources of Hg in the atmosphere (Streets et al., 2005; Zhang et al., 2015), respectively contributing about 47, 18.5 and 17.5 % of total anthropogenically emitted Hg in China(Zhang et al., 2015). In particular, certain events, such as large-scale biomass burning in autumn and excessive coal combustion in the winter heating season, might also have overprinted the concentration of PM${}_{2.5}$-Hg and its isotope composition. In addition to the possible direct emission from the above anthropogenic sources, atmospheric processes may have impacted the PM${}_{2.5}$-Hg isotopic composition, particularly during the long-range transportation of PM${}_{2.5}$-Hg (and thus a long residence time of about a few days to weeks) in the atmosphere (Lin et al., 2007). These potential sources and possible process effects are discussed in the following sections.

Evidence for strong anthropogenic contribution

Anthropogenic emission as the main PM${}_{2.5}$-Hg contributing sources is evidenced by the enrichment factor (EF) of Hg (and other metals), which was a commonly used geochemical indicator for quantifying the enrichment/depletion of a targeted element in environmental samples (Gao et al., 2002; Song et al., 2012; Chen et al., 2014; Mbengue et al., 2014; Lin et al., 2015b). The EF of a given element was calculated using a double normalization (to the less reactive element Al here) and the upper continental crust (UCC) (Rudnick and Gao, 2003) was chosen as the reference (see details in the Supplement). Al is well adapted to this normalization as it usually has no anthropogenic origin and is not readily modified by secondary processes in the atmosphere, and thus was widely used for enrichment calculation in atmospheric pollution studies (Gao et al., 2002; Waheed et al., 2011; Mbengue et al., 2014; Lin et al., 2015b). The calculated results showed (Table S4) high EF(Hg) values for the 14 PM${}_{2.5}$ samples, ranging from 66 to 424 with an average value of 228 $\pm$ 134 (1 SD, $n$ $=$ 14), indicating that PM${}_{2.5}$-Hg pollution was serious (characterized by significant Hg enrichment) in Beijing. As it is a TE, Hg concentration is generally low in natural terrestrial reservoirs (e.g., 50 ppb in UCC) (Rudnick and Gao, 2003). Similar to the UCC, the topsoil was also mainly composed of aluminosilicates with relatively low Hg concentrations (Table S2). Thus, high EF(Hg) values probably imply a strong anthropogenic contribution to Hg in PM${}_{2.5}$. This could be confirmed by very high EF(Hg) values (up to 226 000, Table S4) determined, for example, in three potential source materials collected from the smelting plant. The high EF(Hg) values also emphasize the importance of studying toxic metals such as Hg (and other heavy metals) in atmospheric particles while assessing the potential threat of hazes on human health.

The strong anthropogenic contribution may be also supported by the relationships between Hg and other particulate components in PM${}_{2.5}$. Figure 4a and b show very good correlations between PM${}_{2.5}$-Hg concentration and the volumetric concentrations of PM${}_{2.5}$ and EC, with correlation coefficients ($r^{\mathrm{2}})$ of 0.40 and 0.80, respectively. It is well known that atmospheric pollution due to the high concentrations of PM${}_{2.5}$ and EC mainly results from anthropogenic emissions (Gao et al., 2015; Lin et al., 2015b). PM${}_{2.5}$-Hg also displayed linear relationships with trace metals. Figure 4c and d show the examples with Co and Zn ($r^{\mathrm{2}}$ of 0.74 and 0.44, respectively, $p$ < 0.01). High metal contents in atmospheric particles are generally related to human activities. For example, combustion and smelting release large amount of TEs into the atmosphere (Xu et al., 2004; Nzihou and Stanmore, 2013). The fact that all PM${}_{2.5}$ samples displayed very high EFs for “anthropophile” elements (elements were generally enriched by human activities) (Chen et al., 2014) such as Cd, Cu, Pb, Sb, Se, Tl and Zn (ranging from 10 to 20 869, Table S4) clearly illustrated the anthropogenic contribution to these elements in PM${}_{2.5}$. As a result, fine atmospheric particles in Beijing were strongly enriched in Hg and other TEs, which was likely caused by elevated anthropogenic activities.

Plots of the volumetric Hg concentration versus PM${}_{2.5}$ content (a), EC content (b), and concentrations of Co (c) and Zn (d) for the PM${}_{2.5}$ samples. In both (c) and (d), only 14 PM${}_{2.5}$ samples are shown with Co and Zn data sets, because 9 PM${}_{2.5}$ samples were exhausted after isotope and OC $/$ EC analyses, and only those 14 PM${}_{2.5}$ samples were analyzed for the other elements.

[Figure omitted. See PDF]

Isotopic overprint of potential anthropogenic Hg sources

Hg isotopic signatures may further indicate that human activities contributed to a large proportion of PM${}_{2.5}$-Hg. In this study, all samples displayed a large variation in ${\mathit{\delta }}^{202}$Hg (from $-$2.18 to 0.51 ‰, Table S1), similar to those values (from $-$2.67 to 0.62 ‰, Table S2) determined for the particulate materials from potential sources such as coal combustion (average $-$1.10 $\pm$ 1.20 ‰, 1 SD, $n$ $=$ 8), smelting ($-$0.87 $\pm$ 0.82 ‰, 1 SD, $n$ $=$ 6) and cement plants ($-$1.42 $\pm$ 0.36 ‰, 1 SD, $n$ $=$ 10), as demonstrated in Figs. 2 and 3. This similarity might indicate the emission of these anthropogenic sources as the possible contributing sources of PM${}_{2.5}$-Hg. Though the anthropogenic samples collected in this study could not cover the whole spectrum of anthropogenic contributions, previous studies reported a similar ${\mathit{\delta }}^{202}$Hg range (from $-$3.48 to 0.77 ‰) for potential source materials worldwide (Biswas et al., 2008; Estrade et al., 2011; Sun et al., 2013, 2014; Yin et al., 2014; Wang et al., 2015b; Das et al., 2016). In fact, most PM${}_{2.5}$ samples possessed ${\mathrm{\Delta }}^{199}$Hg similar to those determined in above-mentioned particulate materials ($-$0.27 to 0.04 ‰, Figs. 2 and 3) in this study, suggesting these anthropogenic emission as the major sources of PM${}_{2.5}$-Hg.

Interestingly, Hg isotope compositions were correlated well with the elements such as Co, Ni and Sb (here the mass ratio of a particular element to aluminum was used to cancel out the dilution effect by major mineral phase), as shown in Fig. 5a and b for the example of Co. These correlations might indicate that Hg and some other metals had common provenance, likely from anthropogenic combustion, as discussed above. A careful investigation of the correlations amongst metal elements, along with Hg isotopic data, further indicated anthropogenic source category. The principal component analysis (PCA) of Hg and other TEs (see Table S5) demonstrated that likely four factors might control the variance of the entire data set over four seasons. In accordance with the above discussion, these four factors were likely a mixture of coal combustion and nonferrous metal smelting (characterized by high contents of Pb, Rb, Se, Zn, Tl, Cr and Cd), cement production (enriched in Ca, Sr, Al and Mg), traffic emission and biomass burning, with their contributions estimated to be about 39, 24, 23, and 7 % (Table S5).

Correlations between Hg isotopic composition (${\mathit{\delta }}^{202}$Hg and ${\mathrm{\Delta }}^{199}$Hg) and Co $/$ Al (a, b) and EC $/$ Al (c, d) elemental mass ratios. In all cases, ${\mathit{\delta }}^{202}$Hg values are positively, and ${\mathrm{\Delta }}^{199}$Hg values negatively, correlated with the Co $/$ Al and EC $/$ Al ratios.

[Figure omitted. See PDF]

As a result, the Hg isotopic compositions may potentially suggest that coal combustion, smelting and cement plants were major sources of PM${}_{2.5}$-Hg. The higher EF(Hg) values and the detail investigation of elemental data supported this hypothesis. However, without careful characterization of potential sources, we are unable to quantify the contribution from each source at this stage. It is worth noting that Fig. 6a and b show that ${\mathit{\delta }}^{202}$Hg increased with EF(Hg) ($r^{\mathrm{2}}$ $=$ 0.55), whereas ${\mathrm{\Delta }}^{199}$Hg decreased with EF(Hg) $(r^{\mathrm{2}}=$ 0.36). These correlations may suggest that the large isotope variation in PM${}_{2.5}$-Hg might be mainly controlled by two end members with contrasting ${\mathit{\delta }}^{202}$Hg and ${\mathrm{\Delta }}^{199}$Hg. The end ${\mathrm{\Delta }}^{199}$Hg values of correlations, however, could not be explained by the above-defined anthropogenic sources, which generally had insignificant odd-MIF. The contribution from additional sources or possible processes was thus needed to explain the extreme ${\mathrm{\Delta }}^{199}$Hg values. Accordingly, the ${\mathit{\delta }}^{202}$Hg and ${\mathrm{\Delta }}^{199}$Hg exhibited contrast relationships with the EC $/$ Al ratios (Fig. 5c and d). As relatively higher EC contents were generally derived from coal combustion and biomass burning (Zhang et al., 2008; Saleh et al., 2014), these two non-point emission sources might account for the ${\mathrm{\Delta }}^{199}$Hg end values.

Dominant contribution from coal combustion in winter

High EC content in winter PM${}_{2.5}$ might result from additional coal combustion during the heating season, when coal was widely used in both suburban communities and rural individual families (Wang et al., 2006; Song et al., 2007; Schleicher et al., 2015). This additional coal burning could considerably increase Hg and EC emission, explaining the relatively higher PM${}_{2.5}$-Hg (1340 ng g${}^{-\mathrm{1}}$, $p$ < 0.01) and carbon contents (Table S1). In this study, both ${\mathit{\delta }}^{202}$Hg (mean $-$0.71 $\pm$ 0.37 ‰) and ${\mathrm{\Delta }}^{199}$Hg ($-$0.08 $\pm$ 0.11 ‰, 1 SD, $n$ $=$ 6) values for winter PM${}_{2.5}$ samples were consistent with those in coal (average ${\mathit{\delta }}^{202}$Hg values of $-$0.73 $\pm$ 0.33 ‰ and ${\mathrm{\Delta }}^{199}$Hg of $-$0.02 $\pm$ 0.08 ‰) from northeastern China (Yin et al., 2014), possibly supporting the above conclusion. In addition to EC contents, the Zn $/$ Al ratio may provide information for PM from industrial (e.g., metal smelting) emission sources. In the Zn $/$ Al vs. EC diagram (Fig. 7), all winter samples displayed a linear relationship ($r^{\mathrm{2}}=$ 0.94) different from the samples of other seasons. Compared to the data of other seasons, the volumetric EC concentrations varied greatly in winter, whereas the Zn $/$ Al ratio of the same season remained stable. This variation may be derived from the emission of coal burning, which is characterized by high carbon content but relatively low Zn concentration (Nzihou and Stanmore, 2013; Saleh et al., 2014). This again highlights the dominant contribution from coal combustion. The backward trajectory calculated by the Hybrid Single Particle Lagrangian Integrated Trajectory (HYSPLIT) model (Fig. S1 in the Supplement) showed the dominant northwestern wind in winter. In this case, the fact that the transported air masses were derived from the background region (less populated and underdeveloped) could potentially explain both the lower volume-based concentrations of Hg, TEs (e.g., Zn) and EC (Fig. 7) and the higher mass-based contents of Hg, TEs (e.g., Zn) and EC (Table S1 in the Supplement) in some winter samples. The dilution by this background air could also explain the comparable EC content in winter and autumn (Figs. 1 and 7).

Correlations between Hg isotopic composition (${\mathit{\delta }}^{202}$Hg and ${\mathrm{\Delta }}^{199}$Hg) and Hg enrichment factor EF(Hg) (a, b). The ${\mathit{\delta }}^{202}$Hg value is positively correlated with the EF(Hg), while the ${\mathrm{\Delta }}^{199}$Hg value is negatively correlated with the EF(Hg).

[Figure omitted. See PDF]

Important biomass burning input in autumn

Biomass burning that often occurred in northern China might be the cause of relatively higher EC volumetric concentrations in autumn PM${}_{2.5}$. The HYSPLIT model (Fig. S2) showed that, unlike the winter PM${}_{2.5}$, the samples collected in autumn were strongly impacted by northward wind. Biomass burning that occurred in the south of Beijing during the autumn harvesting season could transport a large amount of EC (and Hg) to Beijing, adding a potential source to PM${}_{2.5}$-Hg. Though biomass burning is not an important source in an annual time scale (from PCA estimation), it may display major contribution in a short time period in autumn. Previous studies showed that this source might account for 20 to 60 % of PM${}_{2.5}$ in Beijing during peak days of biomass burning (Zheng et al., 2005a, b). Isotopically, PM${}_{2.5}$ collected in the arriving air masses from south was characterized by significantly negative ${\mathrm{\Delta }}^{199}$Hg values (from $-$0.54 to $-$0.29 ‰), whereas samples collected in the northwestern wind event exhibited ${\mathrm{\Delta }}^{199}$Hg values close to zero or slightly positive, indicating a negative ${\mathrm{\Delta }}^{199}$Hg signature in biomass burning emission Hg. Our newly obtained data on Hg isotopes from biomass burning showed negative ${\mathrm{\Delta }}^{199}$Hg (which will be published in the future), supporting our hypothesis. Moreover, prior studies have generally reported negative ${\mathrm{\Delta }}^{199}$Hg values for biological samples including foliage (about $-$0.37 ‰), rice stem (about $-$0.37 ‰) and litter (about $-$0.44 ‰) (Demers et al., 2013; Yin et al., 2013; Jiskra et al., 2015), even down to $-$1.00 ‰ for some lichen (Carignan et al., 2009). The odd-MIF signature may be conserved during complete biomass burning as this process would not produce any mass-independent fractionation (Sun et al., 2014; Huang et al., 2015).

Correlations between Zn $/$ Al ratios and EC contents suggest seasonal characteristics of PM${}_{2.5}$ sources with seasonally unique ${\mathrm{\Delta }}^{199}$Hg signatures (in ‰).

[Figure omitted. See PDF]

Interestingly, the autumn PM${}_{2.5}$ had a Zn $/$ Al versus EC correlation ($r^{\mathrm{2}}=$ 0.37) distinctly different from the winter samples, as well as from spring and summer samples (Fig. 7). This difference may imply another carbon-enriched contribution in autumn other than coal combustion. In fact, the high occurrence of biomass burning in the south (Hebei and Henan provinces) may lead to the EC content (volume-based) increasing in autumn air mass. Thus, the high EC air mass input from biomass burning could explain the different trend which defined by autumn PM${}_{2.5}$, while the above-discussed contribution from industries (mainly smelting) could explain the higher Zn (at a given EC content) in summer samples. Though most samples with high EC could result from biomass burning, two autumn samples displaying relatively low EC could be caused by the dilution from northern background air mass (Fig. S2), as demonstrated by the HYSPLIT model.

Contribution from long-range-transported PM${}_{2.5}$-Hg

Besides the dominant contribution from local or regional emissions, long-range-transported Hg might impact on PM${}_{2.5}$-Hg in Beijing (Han et al., 2015; Wang et al., 2015a). As shown in Figs. 1 and 2 and Table S1, the six spring PM${}_{2.5}$ samples and the one early summer sample had much high ${\mathrm{\Delta }}^{199}$Hg (from 0.14 to 0.57 ‰, mean of 0.39 $\pm$ 0.16 ‰, 1 SD, $n$ $=$ 7) and ${\mathrm{\Delta }}^{200}$Hg values (from 0.08 to 0.12 ‰, mean of 0.10 $\pm$ 0.01 ‰, 1 SD, $n$ $=$ 7). These high values could not be explained by the above-defined anthropogenic contributors having generally negative or close to zero MIF (Figs. 2 and 3), yet another contribution or fractionation during atmospheric processing is needed to explain all data sets. The long-range-transported PM${}_{2.5}$ may be such contributor in addition to the direct local or regional anthropogenic emission (Han et al., 2015; Wang et al., 2015a).

The HYSPLIT calculation showed that the arriving air masses of these samples generally came from a long distance (mainly from the north and northwest, Figs. S3 and S4), suggesting a contribution of long-range transportation, given the residence time of PM${}_{2.5}$-Hg (days to weeks) (Lin et al., 2007). Unfortunately, we were not able to collect and analyze the typical long-range-transported Hg in this study. Previous studies have reported that long-range-transported Hg might exhibit relatively higher ${\mathrm{\Delta }}^{199}$Hg (up to 1.16 ‰) due to the extensive photolysis reaction (Chen et al., 2012; Wang et al., 2015b; Yuan et al., 2015). In fact, the samples with significantly positive ${\mathrm{\Delta }}^{199}$Hg were collected during a period (at least 3 days before sampling) with long daily sunshine (> 8.8 h) for Beijing and adjacent regions (Table S1). Such climate conditions might be favorable for photoreduction of atmospheric Hg${}^{\mathrm{2}+}$, which preferentially enriches odd isotopes in solution or aerosols. The fact that the background TSP sample from the Yanqing region had higher ${\mathrm{\Delta }}^{199}$Hg (0.18 ‰, Table S2) than PM${}_{2.5}$ samples collected at the same time in the center of Beijing might suggest higher odd-MIF values for long-range-transported Hg, since the local Hg emission is very limited in this rural area. Moreover, the higher ${\mathrm{\Delta }}^{200}$Hg values (from 0.08 to 0.12 ‰, Table S1) determined in these samples may also indicate the contribution of long-range transportation, since even-MIF was thought to be a conservative indicator of upper atmosphere chemistry (Chen et al., 2012; Cai and Chen, 2016). Since the locally emitted PM${}_{2.5}$-Hg (having lower or close to zero ${\mathrm{\Delta }}^{199}$Hg and ${\mathrm{\Delta }}^{200}$Hg) mainly resided and accumulated in the atmospheric boundary layer (generally < 1000 m), and thus could be largely scavenged by precipitation (Yuan et al., 2015), the higher ${\mathrm{\Delta }}^{199}$Hg values (from 0.06 to 0.14 ‰; see Table S1) for PM${}_{2.5}$ sampled after precipitation event supported the contribution of long-range transport to PM${}_{2.5}$-Hg. Finally, as the background PM${}_{2.5}$ with little input from anthropogenic activities is likely characterized by low contents of trace metals (such as Zn) and organic matter (Song et al., 2007; Zhou et al., 2012), the long-range transport contribution could also explain PM${}_{2.5}$ samples with relatively low EC content and Zn $/$ Al ratio in Fig. 7.

Possible process effects on transported PM${}_{2.5}$-Hg

The atmospheric processes such as secondary aerosol production, adsorption (and desorption) and redox reactions may induce a redistribution of Hg among GEM, RGM and PBM and simultaneously fractionate Hg isotopes in PM${}_{2.5}$, possibly resulting in a difference of Hg isotopic composition between PM${}_{2.5}$ and source materials. Up to now, Hg isotopic fractionation has rarely been reported for Hg redistribution and secondary aerosol formation in the atmosphere. However, the fact that the contents of secondary organic carbon (see detailed calculation in the Supplement) had no correlation ($r^{\mathrm{2}}$ < 0.09, $p$ > 0.18) with either ${\mathit{\delta }}^{202}$Hg or ${\mathrm{\Delta }}^{199}$Hg may imply a limited effect of such processes. Previous studies have showed limited adsorption of Hg${}^{\mathrm{0}}$ on atmospheric particles (Seigneur et al., 1998). More importantly, according to the experiments conducted under aqueous conditions, the adsorption/desorption and precipitation of Hg${}^{\mathrm{2}+}$ may only induce very small MIF of Hg isotopes (Jiskra et al., 2012; Smith et al., 2015), in contrast with our observation. Therefore, the effect of adsorption or precipitation was probably limited to MIF of Hg isotopes in PM${}_{2.5}$. In this study, all 23 PM${}_{2.5}$ samples defined a straight line in Fig. 2 with a ${\mathrm{\Delta }}^{199}$Hg $/$ ${\mathrm{\Delta }}^{201}$Hg slope of about 1.1, consistent with the results of the Hg${}^{\mathrm{2}+}$ photoreduction experiment (Bergquist and Blum, 2007; Zheng and Hintelmann, 2009), suggesting a possible effect of photochemical reduction during PM${}_{2.5}$-Hg transport. Potentially, the enrichment of odd isotopes in reactants (here particles) during these processes can explain the positive ${\mathrm{\Delta }}^{199}$Hg in spring and summer samples. However, most samples collected in autumn and winter displayed significant negative ${\mathrm{\Delta }}^{199}$Hg values (down to $-$0.54 ‰, Figs. 1, 2, 4 and 5, and Table S1). Therefore, the photoreduction of divalent Hg species cannot explain the total variation in Hg isotope ratios determined in all samples, especially the odd-MIF. Moreover, the inverse relationship ($r^{\mathrm{2}}=$ 0.45, $p$ < 0.01) between ${\mathrm{\Delta }}^{199}$Hg and ${\mathit{\delta }}^{202}$Hg was inconsistent with the experimental results of photoreduction that generally showed positive correlation for the residual Hg pool (here particles) (Bergquist and Blum, 2007; Zheng and Hintelmann, 2009). All these arguments suggest that these processes may not be the major mechanism to produce large, even contrasting, Hg isotope variation in Hg-enriched fine atmospheric particles. A recent study reported Hg, isotopic fractionation during Hg${}^{\mathrm{0}}$ oxidation showed a positive relationship between ${\mathrm{\Delta }}^{199}$Hg and ${\mathit{\delta }}^{202}$Hg for Cl-initiated oxidation but a negative relationship for Br-initiated oxidation. Though our PM${}_{2.5}$ samples also displayed a decrease in ${\mathrm{\Delta }}^{199}$Hg with ${\mathit{\delta }}^{202}$Hg (Fig. 2), similar to the Br-initiated oxidation, they had a ${\mathrm{\Delta }}^{199}$Hg $/$ ${\mathrm{\Delta }}^{201}$Hg ratio (1.1) lower than that (1.6 $\pm$ 0.3) of Br-initiated oxidation, and much lower than that (1.9 $\pm$ 0.2) of Cl-initiated oxidation (Sun et al., 2016). Though we cannot exclude the contribution of Hg${}^{\mathrm{0}}$ oxidation to PM${}_{2.5}$-Hg, given the fact that halogen-initiated oxidation would not largely occur in in-land atmospheric boundary layer, oxidation would not be a dominant controlling factor causing the seasonal variation in Hg isotopes in PM${}_{2.5}$ particles. We thus suggest that the contributions from different sources may be the better scenario to explain the seasonal variation in Hg isotopic compositions we measured for the PM${}_{2.5}$ samples.

Conclusions

In summary, our study reported, for the first time, large range and seasonal variations in both MDF and MIF of Hg isotopes in haze particulate (PM${}_{2.5})$ samples collected from Beijing. The strong anthropogenic input to PM${}_{2.5}$-Hg was evidenced by the high enrichment of Hg (and other “anthropophile” elements) and Hg isotopic compositions. Our data showed that mixing of variable contributing sources likely triggered the seasonal variation in Hg isotopic ratio. Major potential contributing sources were identified by coupling Hg isotope data with other geochemical parameters (e.g., PM${}_{2.5}$, EC, element concentrations) and meteorological data and showed variable contribution in four seasons, with continuous industrial input (e.g., smelting, cement production and coal combustion) over the year and predominant contributions from coal combustion and biomass burning in winter and autumn, respectively. In addition to the local and/or regional emissions, long-range-transported Hg was probably also a contributor to PM${}_{2.5}$-Hg, accounting for the relatively higher odd-MIF particularly found in spring and early summer. This study demonstrated the potential use of isotopes for tracing the sources of heavy metals and their vectors in the atmosphere, and stressed the importance of studying toxic metals such as Hg (and other heavy metals) in atmospheric particles while assessing the potential threat of hazes on human health.

The Supplement related to this article is available online at doi:10.5194/acp-16-11773-2016-supplement.

Acknowledgements

We thank J. G. Wiederhold of the University of Vienna and the two anonymous reviewers for their constructive comments and suggestions. This study was financially supported by the National “973” Program (no. 2013CB430001), the “Strategic Priority Research Program” (no. XDB05030302 and XDB05030304), the Natural Science Foundation of China (no. 41273023, U1301231, 41561134017, 41173024) and the “Hundred Talents” project of the Chinese Academy of Sciences. Q. Huang also thanks the China Postdoctoral Science Foundation (no. 2014M550472). Edited by: L. Zhang Reviewed by: J. G. Wiederhold and two anonymous referees